JP2015530775A - Method for controlling mobile communication terminal and radio frequency power amplifier thereof - Google Patents

Abstract

The present invention discloses a method for controlling a mobile communication terminal and its radio frequency power amplifier. The mobile communication terminal includes a signal processing module and a radio frequency power amplifier, and the signal processing module outputs a radio frequency signal corresponding to one group of data packets to a radio frequency signal input terminal of the radio frequency power amplifier, The enable signal is synchronously output to the enable signal input terminal of the radio frequency power amplifier, and the signal processing module periodically stops outputting the enable signal to the enable signal input terminal within the first predetermined duration. The radio frequency signal corresponding to at least one piece of pilot data is output to the radio frequency signal input terminal within the second predetermined duration, and the enable signal is synchronously output to the enable signal input terminal. By using the above disclosed contents, the technical solution disclosed in the present invention can guarantee the normal operation of the uplink traffic channel while effectively reducing the power consumption of the mobile communication terminal. it can.

Description

  This application is a Chinese patent application entitled “MOBILE COMMUNICATIONS TERMINAL, AND METHOD FOR CONTROLLING RADIO FREQUENCY POWER AMPLIFIER THEREOF” filed with the Chinese Patent Office on November 5, 2012, which is incorporated herein by reference in its entirety. Claim priority of 201210436138.7.

  The present invention relates to the field of communication technology, and in particular, to a mobile communication terminal and a method for controlling a radio frequency power amplifier based on the mobile communication terminal.

  In mobile communication terminals such as mobile phones and personal handyphone systems, power amplification processing needs to be performed on radio frequency signals by using a radio frequency power amplifier (RFPA), then The radio frequency signal is sent to the base station by using an antenna. Therefore, the radio frequency power amplifier is usually a module that consumes the maximum amount of power in the mobile communication terminal, and if the operation mode of the radio frequency power amplifier can be appropriately controlled, the amount of electricity is saved, Power consumption can be reduced and standby time can be extended.

  Referring to FIG. 1, FIG. 1 is a schematic diagram of pins of a radio frequency power amplifier in the prior art. As shown in FIG. 1, the radio frequency power amplifier includes an enable signal input terminal EN, a radio frequency signal input terminal RF_in, a radio frequency signal output terminal RF_out, and a power input terminal VDD. The power input terminal VDD acquires power supply to supply power, and the radio frequency signal input terminal RF_in acquires radio frequency signals. When the enable signal input acquires the enable signal, the radio frequency power amplifier enters an operation state, performs power amplification processing on the acquired radio frequency signal, and outputs it from the radio frequency signal output terminal RF_out. If the end EN does not acquire the enable signal, the radio frequency power amplifier enters a sleep state and does not perform power amplification processing on the acquired radio frequency signal. The power consumption of the radio frequency power amplifier in the resting state is much smaller than the power consumption of the radio frequency power amplifier in the operating state.

  Referring to FIG. 2, FIG. 2 is a sequence diagram of input of an enable signal at the enable signal input terminal EN of the radio frequency power amplifier in the prior art. In the prior art, a mobile communication terminal establishes an uplink traffic channel with a base station, and the mobile communication terminal sends an uplink data signal to the base station via the uplink traffic channel. As shown in FIG. 2, within the duration 0-T1 ′, the enable signal is input to the enable signal input EN, the radio frequency power amplifier enters the operating state, during which the uplink traffic channel is established, The mobile communication terminal needs to send a radio frequency signal corresponding to the signaling used to establish the uplink traffic channel to the base station. Therefore, the radio frequency power amplifier needs to perform power amplification processing on the radio frequency signal in order to guarantee establishment of the uplink traffic channel.

  Within the duration T1′-T2 ′, an enable signal is input to the enable signal input EN, and the radio frequency power amplifier operates normally, during which the mobile communication terminal sends a group of data packets to the base station There is a need, where a group of data packets needs to be modulated into a radio frequency signal before being sent and a power amplification process is performed on the radio frequency signal. Therefore, in the meantime, it is necessary to enable the radio frequency power amplifier to perform power amplification processing on radio frequency signals corresponding to groups of data packets.

  After the uplink traffic channel is established, data packets are generally sent intermittently rather than continuously. That is, after transmission of a group of data packets is complete, another group of data packets needs to be waited for a period of time before being generated and sent to the base station via the uplink traffic channel.

  Thus, in the prior art, the enable signal input terminal is within the duration T2′-T3 ′ between the time when transmission of a group of data packets is completed and the time when another group of data packets is generated. The output of the enable signal to EN is stopped, so that the radio frequency power amplifier enters a dormant state. However, when another group of data packets is generated, the enable signal is output to the enable signal input EN, so that the radio frequency power amplifier enters an operating state and the radio frequency power amplifier Power amplification processing is performed on the radio frequency signals corresponding to the group, thereby implementing energy saving.

  After the processing for the radio frequency signal corresponding to another group of data packets is completed, the output of the enable signal to the enable signal input EN is stopped within the duration T4'-T5 ', resulting in a radio frequency power amplifier Enters a dormant state, and at time T5 ′ when the uplink traffic channel needs to be removed, an enable signal is output to enable the radio frequency power amplifier so that the power amplification process Ensure that in the power amplifier can be performed on radio frequency signals corresponding to the signaling signals used to remove the uplink traffic channel. After the uplink traffic channel is removed, that is, at time T6 ′, the output of the enable signal is stopped and the radio frequency power amplifier stops operating.

  In order to achieve the purpose of reducing power consumption, in the prior art, the radio frequency power amplifier is in duration T2′-T3 ′ and duration T4′-T5 ′ in which the uplink traffic channel is idle. Controlled to be in the dormant state, however, the power amplification process of the radio frequency power amplifier corresponds to the pilot data and cannot be performed on the radio frequency signal generated by the mobile communication terminal during that time, As a result, the base station typically does not receive radio frequency signals that correspond to pilot data and are sent by mobile communication terminals, and therefore cannot evaluate channel quality according to the radio frequency signals. In this case, if the base station does not detect the radio frequency signal corresponding to the pilot data within the time interval exceeding the pilot detection timeout duration, the base station indicates that the mobile communication terminal is offline and the uplink traffic channel is abnormal. And the downlink traffic data channel can be actively closed, resulting in a data service call drop, thereby degrading the communication quality.

  The technical problem mainly solved by the present application is to provide an embodiment of a method for controlling a mobile communication terminal and its radio frequency power amplifier, which effectively reduces power consumption. However, normal operation of the uplink traffic channel can be guaranteed.

  According to a first aspect, a mobile communication terminal is provided, the mobile communication terminal establishes an uplink traffic channel with a base station, the mobile communication terminal includes a signal processing module and a radio frequency power amplifier, and a signal The processing module outputs a radio frequency signal corresponding to one group of data packets to the radio frequency signal input terminal of the radio frequency power amplifier and synchronously outputs an enable signal to the enable signal input terminal of the radio frequency power amplifier. The time after the radio frequency signal corresponding to the group of data packets is output to the radio frequency signal input terminal and the time when the radio frequency signal corresponding to another group of data packets is output to the radio frequency signal input terminal Within the duration between the time, the signal processing module is enabled at the enable signal input within the first predetermined duration Is periodically stopped, a radio frequency signal corresponding to at least one piece of pilot data is output to the radio frequency signal input terminal within a second predetermined duration, and an enable signal is output to the enable signal input terminal The first predetermined duration is shorter than the pilot detection timeout duration of the base station, and a group of data packets and another group of data packets are transmitted over the uplink traffic channel Data packets that need to be transmitted.

  Regarding the mounting method of the first aspect, in the first possible mounting method, after outputting a radio frequency signal corresponding to a group of data packets to a radio frequency signal input terminal, the signal processing module is within a preset extension duration. Further, the enable signal is continuously output to the enable signal input terminal.

  Regarding the implementation method of the first aspect, in a second possible implementation method, a group of data packets, another group of data packets, and pilot data are recorded in one or more radio frames.

  With respect to the mounting method of the first aspect, in a third possible mounting method, the radio frequency power amplifier includes a radio frequency signal corresponding to a group of data packets input to the radio frequency signal input terminal and a data packet separately The power amplification processing is executed on the radio frequency signal corresponding to the group and the radio frequency signal corresponding to at least one piece of pilot data.

  Regarding the third possible implementation method of the first aspect, in a fourth possible implementation method, the mobile communication terminal further comprises an antenna, the radio frequency power amplifier further comprises a radio frequency signal output, and a radio frequency The power amplifier uses the radio frequency signal output to provide the antenna with a radio frequency signal corresponding to a group of data packets and a radio frequency corresponding to another group of data packets after power amplification processing. The signal and a radio frequency signal corresponding to at least one piece of pilot data are transmitted, and the antenna transmits to the base station a radio frequency signal corresponding to a group of data packets, after power amplification processing, and a data packet A radio frequency signal corresponding to another group and a radio frequency signal corresponding to at least one piece of pilot data are sent.

  According to a second aspect, a method is provided for controlling a radio frequency power amplifier of a mobile communication terminal, the mobile communication terminal establishes an uplink traffic channel with a base station, and the mobile communication terminal The method includes a module and a radio frequency power amplifier, wherein the method outputs a radio frequency signal corresponding to one group of data packets to a radio frequency signal input terminal of the radio frequency power amplifier and inputs an enable signal of the radio frequency power amplifier. A step of synchronously outputting an enable signal to an end, a time after a radio frequency signal corresponding to a group of data packets is output to a radio frequency signal input end, and a radio frequency signal corresponding to another group of data packets Enable signal within a first predetermined duration within a duration between when the signal is output to the radio frequency signal input The output of the enable signal to the power terminal is periodically stopped, and the radio frequency signal corresponding to at least one piece of pilot data is output to the radio frequency signal input terminal within the second predetermined duration, and the enable signal is input. Synchronously outputting an enable signal at an end, wherein the first predetermined duration is shorter than the pilot detection timeout duration of the base station, and the group of data packets and another group of data packets are: Outputting a data packet that needs to be transmitted over the uplink traffic channel.

  Regarding the implementation method of the second aspect, in the first possible implementation method, after the radio frequency signal corresponding to the group of data packets is output to the radio frequency signal input terminal, the enable signal is within the preset extension duration. Further output continues to the enable signal input terminal.

  Regarding the implementation method of the second aspect, in a second possible implementation method, a group of data packets, another group of data packets, and pilot data are recorded in one or more radio frames.

  With respect to the mounting method of the second aspect, in a third possible mounting method, the radio frequency power amplifier is configured to input a radio frequency signal corresponding to a group of data packets input to a radio frequency signal input terminal and a data packet separately The power amplification processing is executed on the radio frequency signal corresponding to the group and the radio frequency signal corresponding to at least one piece of pilot data.

  Regarding the third implementation method of the second aspect, in a fourth possible implementation method, the mobile communication terminal further includes an antenna, the radio frequency power amplifier further comprises a radio frequency signal output, and the radio frequency power amplifier Is a radio frequency signal corresponding to a group of data packets and a radio frequency signal corresponding to another group of data packets, which are after power amplification processing, to the antenna by using a radio frequency signal output end. A radio frequency signal corresponding to at least one piece of pilot data, and an antenna to the base station after power amplification processing, the radio frequency signal corresponding to the group of data packets and another of the data packets A radio frequency signal corresponding to the group and a radio frequency signal corresponding to at least one piece of pilot data are transmitted.

  Unlike the situation in the prior art, according to the method for controlling a mobile communication terminal and its radio frequency power amplifier in an embodiment of the present application, when the uplink traffic channel is idle, the radio frequency power amplifier is In order to pause, the output of the enable signal to the enable signal input of the radio frequency power amplifier is periodically stopped within a first predetermined duration and the second predetermined time is used to operate the radio frequency power amplifier. The radio frequency signal corresponding to at least one piece of pilot data is output to the radio frequency signal input terminal of the radio frequency power amplifier and the enable signal is output synchronously to the enable signal input terminal. Since the radio frequency power amplifier is idle within a first predetermined duration, power consumption can be reduced. Within a second predetermined duration, a radio frequency power amplifier is enabled and a radio frequency signal corresponding to at least one piece of pilot data is output at the radio frequency signal input, resulting in at least one piece of pilot data. It can be ensured that the corresponding radio frequency signal can be input to a radio frequency power amplifier enabled for subsequent processing, and in the adjacent period, the time interval between adjacent radio frequency signals corresponding to pilot data Is the first predetermined duration that is shorter than the pilot detection timeout duration for the pilot data of the base station, so that the base station has a radio frequency signal corresponding to the pilot data for the first predetermined duration. Because it is not detected in time, the mobile communication device does not determine that it is offline, thereby increasing the uplink traffic To ensure the normal operation of the Yaneru.

1 is a schematic diagram of pins of a radio frequency power amplifier in the prior art. FIG. It is a sequence diagram of the input of the enable signal in the enable signal input terminal of the radio frequency power amplifier in a prior art. 1 is a schematic diagram of a circuit structure of a mobile communication terminal according to a first embodiment of the present invention. FIG. 3 is a sequence diagram of power supply of the radio frequency power amplifier according to the first embodiment of the present invention. 4 is a flowchart of a method for controlling a radio frequency power amplifier of a mobile communication terminal according to a second embodiment of the present invention;

  Embodiments of the present invention provide a mobile communication terminal, which establishes an uplink traffic channel with a base station, the mobile communication terminal including a signal processing module and a radio frequency power amplifier, The module outputs a radio frequency signal corresponding to one group of data packets to the radio frequency signal input terminal of the radio frequency power amplifier, and outputs an enable signal synchronously to the enable signal input terminal of the radio frequency power amplifier, The time after the radio frequency signal corresponding to the group of data packets is output to the radio frequency signal input terminal, and the time when the radio frequency signal corresponding to another group of data packets is output to the radio frequency signal input terminal Within the duration between and the signal processing module is enabled at the enable signal input within the first predetermined duration Is periodically stopped, a radio frequency signal corresponding to at least one piece of pilot data is output to the radio frequency signal input terminal within a second predetermined duration, and an enable signal is output to the enable signal input terminal The first predetermined duration is shorter than the pilot detection timeout duration of the base station, and a group of data packets and another group of data packets are transmitted over the uplink traffic channel Data packets that need to be transmitted.

  Embodiments of the present invention further provide a method for controlling a radio frequency power amplifier of a mobile communication terminal, wherein the mobile communication terminal establishes an uplink traffic channel with the base station, and the mobile communication terminal The method includes a module and a radio frequency power amplifier, wherein the method outputs a radio frequency signal corresponding to one group of data packets to a radio frequency signal input terminal of the radio frequency power amplifier and inputs an enable signal of the radio frequency power amplifier. A step of synchronously outputting an enable signal to an end, a time after a radio frequency signal corresponding to a group of data packets is output to a radio frequency signal input end, and a radio frequency signal corresponding to another group of data packets Enabled within the first predetermined duration within the duration between when the signal is output at the radio frequency signal input The output of the enable signal to the signal input terminal is periodically stopped, and a radio frequency signal corresponding to at least one piece of pilot data is output to the radio frequency signal input terminal within the second predetermined duration, and the enable signal A step of synchronously outputting an enable signal to an input terminal, wherein the first predetermined duration is shorter than a pilot detection timeout duration of the base station, and a group of data packets and another group of data packets are Outputting data packets that need to be transmitted over the uplink traffic channel.

  By using the above technical solution, the method for controlling a mobile communication terminal and its radio frequency power amplifier in an embodiment of the present invention can be improved while effectively reducing the power consumption of the mobile communication terminal. Normal operation of the link traffic channel can be guaranteed.

  In the following, a method for controlling a mobile communication terminal and its radio frequency power amplifier according to an embodiment of the present invention will be described with reference to a specific embodiment.

  Referring to FIG. 3, FIG. 3 is a schematic diagram of a circuit structure of a mobile communication terminal according to the first embodiment of the present invention. As shown in FIG. 3, in the present embodiment, the mobile communication terminal 10 of the present invention includes a signal processing module 101, a power supply module 102, a radio frequency power amplifier 103, and an antenna 104, where the mobile The communication terminal 10 performs wireless communication with a base station (not shown) by using the antenna 104.

  The radio frequency power amplifier 103 corresponds to the radio frequency power amplifier described in FIG. 1, and the radio frequency power amplifier 103 includes an enable signal input terminal EN ′, a radio frequency signal input terminal RF_in ′, and a radio frequency signal output terminal RF_out. 'And a power input terminal VDD'. The power input terminal VDD ′ obtains power from the power supply module 102 to supply power, the radio frequency signal input terminal RF_in ′ obtains a radio frequency signal from the signal processing module 101, and the enable signal input terminal EN When the enable signal is acquired from the signal processing module 101, the radio frequency power amplifier 103 enters an operating state, performs power amplification processing on the acquired radio frequency signal, and outputs from the radio frequency signal output terminal RF_out '. When the enable signal input terminal EN ′ does not acquire an enable signal from the signal processing module 101, the radio frequency power amplifier 103 enters a sleep state and does not perform power amplification processing on the acquired radio frequency signal. . The power consumption of the radio frequency power amplifier 103 in the dormant state is much smaller than the power consumption in the operating state.

  Referring to FIG. 4, FIG. 4 is a sequence diagram of input of an enable signal at the enable signal input terminal EN ′ of the radio frequency power amplifier 103 according to the first embodiment of the present invention. As shown in FIG. 4, in FIG. 4, the horizontal axis represents time, and the vertical axis represents whether the enable signal is input to the enable signal input terminal EN ′. When the vertical axis value is “0”, it indicates that the enable signal is not input to the enable signal input terminal EN ′. When the vertical axis value is “1”, the enable signal is input to the enable signal input terminal EN ′. Indicates input.

  As shown in FIG. 4, in order to put the radio frequency power amplifier 103 into an operating state within the duration 0 to T1, the signal processing module 101 is up to the radio frequency signal input terminal RF_in ′ of the radio frequency power amplifier 103. A radio frequency signal corresponding to signaling used for establishing a link channel is output, and an enable signal is synchronously output to an enable signal input terminal EN ′. Meanwhile, in order to cope with establishing an uplink traffic channel with the mobile communication terminal 10, the radio frequency power amplifier 103 performs power amplification processing on the radio frequency signal and outputs the radio frequency signal output terminal RF_out ′. The antenna 104 outputs a radio frequency signal after power amplification processing to the antenna 104, the antenna 104 sends the radio frequency signal to the base station, and after acquiring the radio frequency signal, the base station Obtain the signaling used to establish the uplink channel.

  In order to put the radio frequency power amplifier 103 into an operating state within the duration T1 to T2, the signal processing module 101 has a radio frequency signal corresponding to one group of data packets at the signal input end of the radio frequency power amplifier 103. And the enable signal is synchronously output to the enable signal input terminal EN ′ of the radio frequency power amplifier 103. Meanwhile, the radio frequency power amplifier 103 performs power amplification processing on the radio frequency signal, and outputs a radio frequency signal after power amplification processing from the radio frequency signal output terminal RF_out ′ to the antenna 104, After the antenna 104 sends a radio frequency signal to the base station and obtains the radio frequency signal, the base station obtains that group of data packets through a demodulation process, thereby performing the transfer of the data packet. obtain.

  The signal processing module 101 outputs a radio frequency signal corresponding to the group of data packets to the signal input terminal of the radio frequency power amplifier 103 in order to put the radio frequency power amplifier 103 into an operating state within the duration T2 to T3. After that, the enable signal is continuously output to the enable signal input terminal EN ′. Durations T2-T3 are preset extension durations that output an enable signal to the radio frequency power amplifier 103 before transmission is completed (eg, the output of the signal processing module 101 is delayed for various reasons). Radio frequency signal corresponding to the group of data packets for the power amplification process in order to put the radio frequency power amplifier 103 into a dormant state and avoid a data loss situation. The purpose is to guarantee that the signal is completely sent to the frequency signal input terminal RF_in '.

  In alternative embodiments of the invention, the preset extension duration may not be set as needed. The preset extension duration may not be set as required by a system with low requirements for data transmission accuracy.

  Within the duration T3 to T4, the signal processing module 101 periodically stops outputting the enable signal to the enable signal input EN 'within the first predetermined duration Toff, and the pilot at the signal input A radio frequency signal corresponding to at least one piece of data is output, and an enable signal is synchronously output to the enable signal input terminal EN ′ within a second predetermined duration Ton. Within the duration T3-T4, the uplink traffic channel is idle to reduce power consumption, and in this embodiment, the radio frequency power amplifier 103 is idle when the uplink traffic channel is idle. In order to ensure that the state can be maintained periodically, the enable signal is periodically stopped from being output to the enable signal input EN ′ within a first predetermined duration Toff.

  After the mobile communication terminal 10 establishes an uplink traffic channel with the base station, the base station intermittently detects whether pilot data is obtained from the mobile communication terminal 10 and the pilot data is within a predetermined duration. The mobile communication terminal 10 determines that the mobile communication terminal 10 is offline, where the predetermined duration is a pilot detection timeout duration.

  In order to avoid that the base station determines that the mobile communication terminal 10 is offline because pilot data is not detected within the time interval that is the pilot detection timeout duration, in the present embodiment, the second predetermined duration is used. Within time Ton, the signal processing module 101 outputs a radio frequency signal corresponding to at least one piece of pilot data to the signal input terminal, and outputs an enable signal synchronously to the enable signal input terminal EN ′, The setting is made such that the predetermined duration Toff is set to be shorter than the pilot detection timeout duration of the base station.

  Within the second predetermined duration Ton, the radio frequency power amplifier 103 is enabled and a radio frequency signal corresponding to at least one piece of pilot data is output to the radio frequency signal input RF_in ′, so that the pilot data It can be assured that a radio frequency signal corresponding to at least one piece can be input to a radio frequency power amplifier 103 enabled for subsequent processing, and in adjacent periods, adjacent radio frequency signals corresponding to pilot data Since the time interval between is a first predetermined duration Toff, which is shorter than the pilot detection timeout duration for the pilot data of the base station, the base station has a radio frequency signal corresponding to the pilot data 1 is not detected within a predetermined duration Toff of 1, so it is not determined that the mobile communication terminal 10 is offline, thereby the uplink Ensure normal operation of the traffic channel.

  In order to put the radio frequency power amplifier 103 into the operating state within the duration T4 to T5, the signal processing module 101 outputs a radio frequency signal corresponding to another group of data packets to the radio frequency signal input terminal RF_in ′. Then, the enable signal is synchronously output to the enable signal input terminal EN ′ of the radio frequency power amplifier 103. Another group of data packets and the above group of data packets are data packets that need to be transmitted over the same uplink traffic channel, during which the radio frequency power amplifier 103 is connected to the radio frequency signal. The power amplification process is performed, and the radio frequency signal that is the result of the power amplification process is output from the radio frequency signal output terminal RF_out ′ to the antenna 104. The antenna 104 sends the radio frequency signal to the base station, After obtaining the signal, the base station may obtain that other group of data packets via a demodulation process, thereby performing the transfer of the data packets.

  In order to put the radio frequency power amplifier 103 into an operating state within the duration T5 to T6, the signal processing module 101 has a radio frequency signal corresponding to another group of data packets at the signal input end of the radio frequency power amplifier 103. Is continuously output from the enable signal input terminal EN ′. Durations T5-T6 are preset extension durations that output an enable signal to the radio frequency power amplifier 103 before transmission is completed (eg, the output of the signal processing module 101 is delayed for various reasons). Radio frequency signal corresponding to the group of data packets for the power amplification process in order to put the radio frequency power amplifier 103 into a dormant state and avoid a data loss situation. The purpose is to guarantee that the signal is completely sent to the frequency signal input terminal RF_in '. The function of the radio frequency power amplifier 103 corresponds to the function within the above-described durations T2 to T3.

  In alternative embodiments of the invention, the preset extension duration may not be set as needed. The preset extension duration may not be set if the requirements for data transmission accuracy are not high due to system requirements.

  Within the duration T6 to T7, the signal processing module 101 cycles the output of the enable signal to the enable signal input EN ′ within the first predetermined duration Toff when the uplink traffic channel is idle. The radio frequency signal corresponding to at least one piece of pilot data is output to the signal input terminal, and the enable signal is synchronously output to the enable signal input terminal EN ′ within the second predetermined duration Ton. . The mode of operation of the signal processing module 101 and the radio frequency power amplifier 103 within the duration T5 to T6 matches the mode of operation within the duration T3 to T4, and details are not repeatedly described herein.

  The duration T7-T8 is the time required to remove the uplink traffic channel, and within that duration, the signal processing module 101 The radio frequency signal corresponding to the signaling used to remove the uplink channel is output to the radio frequency signal input terminal RF_in ′ of the power amplifier 103, and the enable signal is synchronously output to the enable signal input terminal EN ′. . Meanwhile, in order to cope with removing the uplink traffic channel, the radio frequency power amplifier 103 performs power amplification processing on the radio frequency signal and amplifies the power from the radio frequency signal output terminal RF_out ′ to the antenna 104. After processing, the radio frequency signal is output, antenna 104 sends the radio frequency signal to the base station, and after acquiring the radio frequency signal, the base station removes the uplink channel through the demodulation process Get the signaling used to

  In the present invention, for ease of explanation, via the uplink traffic channel within the duration T1-T7 between the time after the uplink traffic channel is established and the time when the removal of the uplink traffic channel starts. Note that only one group of data packets and another group of data packets are used to represent transmitted data packets. However, in practical applications, multiple intermittent groups of data packets usually need to be sent over the uplink traffic channel. Multiple intermittent groups of data packets may be spaced apart by a specific duration, and within a specific duration, the uplink service communication channel becomes idle. According to the idea of the present invention, within a specific duration, the signal processing module 101 periodically stops outputting an enable signal to the enable signal input EN 'within a first predetermined duration Toff. The radio frequency signal corresponding to at least one piece of pilot data is output to the signal input terminal, and the enable signal is synchronously output to the enable signal input terminal EN ′ within the second predetermined duration Ton. Thus, within a certain duration, the radio frequency power amplifier 103 can become dormant within a first predetermined duration Toff, and the base station can detect the pilot signal, thereby In addition to reducing power consumption, it is also guaranteed to maintain channel stability.

  Further, the above group of data packets, another group of data packets, and pilot data are recorded in one or more radio frames. Preferably, it is desirable that a piece of pilot data is recorded in one radio frame. When a piece of pilot data is recorded in one radio frame, the signal processing module 101 transmits a radio frequency corresponding to the two pieces of pilot data to the radio frequency signal input RF_in ′ within a second predetermined duration Ton. The second predetermined duration Ton can be set correspondingly longer than the duration of the two radio frames, so that the base station within the second predetermined duration Ton Ensure that at least one piece of pilot data can be obtained.

  Hereinafter, referring to FIG. 5, FIG. 5 is a flowchart of a method for controlling the radio frequency power amplifier 103 of the mobile communication terminal 10 according to the second embodiment of the present invention. As shown in FIG. 5, the method includes the following steps.

  Step 301: Output a radio frequency signal corresponding to one group of data packets to the radio frequency signal input terminal RF_in ′ of the radio frequency power amplifier 103, and send an enable signal to the enable signal input terminal EN ′ of the radio frequency power amplifier 103. Output synchronously.

  Step 302: The time after the radio frequency signal corresponding to the group of data packets is output to the radio frequency signal input terminal RF_in ′, and the radio frequency signal corresponding to another group of data packets is the radio frequency signal input terminal RF_in ′. The output of the enable signal to the enable signal input EN 'within the first predetermined duration Toff within the duration between the time when the signal is output to the radio frequency signal input periodically A radio frequency signal corresponding to at least one piece of pilot data is output to the end RF_in ′, and an enable signal is synchronously output to the enable signal input end EN ′ within the second predetermined duration Ton.

  The first predetermined duration Toff above is shorter than the pilot detection timeout duration of the base station, and a group of data packets and another group of data packets need to be transmitted over the uplink traffic channel. A data packet.

  The above steps 301 to 302 are all executed by the signal processing module 101 shown in FIG. 2, and since the above steps have been described in detail in the embodiment shown in FIG. 2, the details will not be repeated here. .

  Therefore, based on the above disclosed content, according to the technical solution disclosed in the present invention, when the uplink traffic channel is in an idle state, in order to pause the radio frequency power amplifier 103, the first predetermined The output of the enable signal to the enable signal input EN ′ of the radio frequency power amplifier 103 is periodically stopped within the duration Toff of the radio frequency power amplifier 103 to operate the radio frequency power amplifier 103 for a second predetermined duration Ton A radio frequency signal corresponding to at least one piece of pilot data is output to the radio frequency signal input terminal RF_in ′ of the radio frequency power amplifier 103, and an enable signal is output synchronously to the enable signal input terminal EN ′. Since the radio frequency power amplifier 103 is paused within the first predetermined duration Toff, the power consumption can be reduced. Within a second predetermined duration Ton, the radio frequency power amplifier 103 is enabled and a radio frequency signal corresponding to at least one piece of pilot data is output to the radio frequency signal input RF_in ′, resulting in pilot data Radio frequency signal corresponding to at least one of the radio frequency power amplifiers 103 can be input to the radio frequency power amplifier 103 enabled for subsequent processing, and adjacent radio frequencies corresponding to pilot data can be Since the time interval between the signals is the first predetermined duration Toff, which is shorter than the pilot detection timeout duration for the pilot data of the base station, the base station has the radio frequency signal corresponding to the pilot data Since it is not detected within the first predetermined duration Toff, it is not determined that the mobile communication terminal 10 is offline, thereby Guarantees normal operation of the link traffic channel.

  The above description is only an embodiment of the present invention, and does not limit the patent scope of the present invention. All equivalent structures or equivalent processing changes made either in accordance with the description of the invention and the accompanying drawings or by applying the invention directly or indirectly to other related technical fields It shall fall within the protection scope of the present invention.

10 Mobile communication terminals
101 Signal processing module
102 Power supply module
103 RF power amplifier
104 Antenna

Claims (10)

A mobile communication terminal for establishing an uplink traffic channel with a base station, comprising a signal processing module and a radio frequency power amplifier,
The signal processing module outputs a radio frequency signal corresponding to one group of data packets to a radio frequency signal input terminal of the radio frequency power amplifier, and synchronizes an enable signal with an enable signal input terminal of the radio frequency power amplifier. Configured to output automatically,
The time after the radio frequency signal corresponding to the group of data packets is output to the radio frequency signal input terminal and the radio frequency signal corresponding to another group of data packets are output to the radio frequency signal input terminal The signal processing module periodically stops outputting the enable signal to the enable signal input terminal within a first predetermined duration within a duration between A radio frequency signal corresponding to at least one piece of pilot data is output to the radio frequency signal input terminal within a predetermined duration of time, and the enable signal is synchronously output to the enable signal input terminal, The first predetermined duration is shorter than the pilot detection timeout duration of the base station, and the group of data packets and the data packet Serial and another group is a data packet that needs to be transmitted over the uplink traffic channel, the mobile communication terminal.   After outputting the radio frequency signal corresponding to the group of data packets to the radio frequency signal input terminal, the signal processing module continues to output the enable signal to the enable signal input terminal within a preset extension duration. The mobile communication terminal according to claim 1, further configured as follows.   The mobile communication terminal of claim 1, wherein the group of data packets, the another group of data packets, and the pilot data are recorded in one or more radio frames.   The radio frequency power amplifier is input to the radio frequency signal input terminal, the radio frequency signal corresponding to the group of data packets, the radio frequency signal corresponding to the another group of data packets, and pilot data The mobile communication terminal according to claim 1, wherein the mobile communication terminal is configured to execute a power amplification process on the radio frequency signal corresponding to the at least one piece.   The mobile communication terminal further includes an antenna, the radio frequency power amplifier further includes a radio frequency signal output terminal, and the radio frequency power amplifier uses the radio frequency signal output terminal to connect the antenna to the antenna. After the power amplification process, the radio frequency signal corresponding to the group of data packets, the radio frequency signal corresponding to the other group of data packets, and the at least one piece of pilot data The radio frequency signal corresponding to the group of data packets, the antenna being after the power amplification process, and the antenna is configured to transmit the radio frequency signal to the base station. The radio frequency signal corresponding to a group of and the no-frequency signal corresponding to the at least one piece of pilot data. Configured to send a frequency signal, the mobile communication terminal according to claim 4. A method for controlling a radio frequency power amplifier of a mobile communication terminal, wherein the mobile communication terminal establishes an uplink traffic channel with a base station, the mobile communication terminal comprising a signal processing module and a radio frequency power amplifier And the method comprises:
Outputting a radio frequency signal corresponding to one group of data packets to a radio frequency signal input terminal of the radio frequency power amplifier, and outputting an enable signal synchronously to an enable signal input terminal of the radio frequency power amplifier; ,
The time after the radio frequency signal corresponding to the group of data packets is output to the radio frequency signal input terminal and the radio frequency signal corresponding to another group of data packets are output to the radio frequency signal input terminal And periodically stopping outputting the enable signal to the enable signal input terminal within a first predetermined duration within a duration between the first predetermined duration and within a second predetermined duration Outputting a radio frequency signal corresponding to at least one piece of pilot data to the radio frequency signal input terminal, and synchronously outputting the enable signal to the enable signal input terminal, wherein the first predetermined signal The duration is less than the pilot detection timeout duration of the base station, and the group of data packets and the other group of data packets Uplink is a data packet that needs to be transmitted over a traffic channel, and outputting method.   The enable signal continues to be further output to the enable signal input within a preset extension duration after the radio frequency signal corresponding to the group of data packets is output to the radio frequency signal input. The method described in 1.   The method of claim 6, wherein the group of data packets, the another group of data packets, and the pilot data are recorded in one or more radio frames.   The radio frequency power amplifier is input to the radio frequency signal input terminal, the radio frequency signal corresponding to the group of data packets, the radio frequency signal corresponding to the another group of data packets, and pilot data The method according to claim 6, wherein a power amplification process is performed on the radio frequency signal corresponding to the at least one piece.   The mobile communication terminal further includes an antenna, the radio frequency power amplifier further includes a radio frequency signal output terminal, and the radio frequency power amplifier uses the radio frequency signal output terminal to connect the antenna to the antenna. After the power amplification process, the radio frequency signal corresponding to the group of data packets, the radio frequency signal corresponding to the other group of data packets, and the at least one piece of pilot data A radio frequency signal, and the antenna corresponds to the radio frequency signal corresponding to the group of data packets and the another group of data packets that are after the power amplification process to the base station The radio frequency signal and the radio frequency signal corresponding to the at least one piece of pilot data. That The method of claim 9.

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